Distinct Roles for Alpha- and Beta-Band Oscillations during Mental Simulation of Goal-Directed Actions

Brinkman, Loek; Stolk, Arjen; Dijkerman, H. Chris; Lange, Floris P. de; Toni, Ivan

doi:10.1523/jneurosci.2039-14.2014

Cited by 168 publications

(155 citation statements)

References 67 publications

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“…This rotation would arguably require a greater level of processing, and may explain Frenkel-Toledo and colleagues ' (2013) finding that an allocentric perspective of a movement induced greater -suppression compared to an egocentric perspective, as it is known that sensorimotor suppression is enhanced by task demands and cognitive load (Klimesch, Schimke, & Pfurtscheller, 1993;Klimesch et al, 1998;Brinkman et al, 2014). However, we did not observe a significant effect for the factor perspective, suggesting that this possibility is unlikely.…”

Section: Involvement Of  In Processing Of Allocentric Hands Movementmentioning

confidence: 48%

Transcranial alternating current stimulation to the inferior parietal lobe decreases mu suppression to egocentric, but not allocentric hand movements

2017

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Egocentric vs. allocentric perspective during observation of hand movements has been related to self-other differentiation such that movements observed from an egocentric viewpoint have been considered as self-related while movements observed from an allocentric viewpoint have been considered as belonging to someone else. Correlational studies have generally found that egocentric perspective induces greater neurophysiological responses and larger behavioural effects compared to an allocentric perspective. However, recent studies question previous findings by reporting greater () suppression and greater transcranial magnetic stimulation (TMS) induced motor-evoked potentials (MEPs) during observation of allocentric compared to egocentric movements. Furthermore, selfother differentiation has been generally related to activity within the inferior parietal lobe (IPL), but direct evidence for a causal and functional role of IPL in self-other differentiation is lacking. The current study was therefore designed to investigate the influence that IPL exerts on self-other differentiation. To this aim, we measured the impact of individually adjusted alpha-tuned transcranial alternating current stimulation (tACS) applied over IPL on -suppression during hands movement observation from an egocentric and allocentric perspective. Electroencephalography (EEG) was recorded during movement observation before and immediately after tACS. Results demonstrated that tACS decreased -reactivity over sensorimotor (but not visual) regions for egocentric (but not allocentric) movement observation providing direct evidence for a causal involvement of IPL in the observation of selfbut not other-related hands movement.

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Section: Involvement Of  In Processing Of Allocentric Hands Movementmentioning

confidence: 48%

Transcranial alternating current stimulation to the inferior parietal lobe decreases mu suppression to egocentric, but not allocentric hand movements

2017

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“…Within cortex, the sensorimotor ␤-rhythm is classically thought to arise from motor, rather than somatosensory, regions (Brovelli et al 2002;Pfurtscheller et al 1997) and, therefore, has been mainly considered as a motor rhythm. In line with this, there is extensive evidence for a modulation of this rhythm by most aspects of movement: from movement execution (Jasper and Penfield 1949;Rougeul et al 1979), offset (Pfurtscheller et al 1997(Pfurtscheller et al , 1998, planning (Leocani et al 1997), preparation (Pfurtscheller et al 1998;Zhang et al 2008), inhibition (Pogosyan et al 2009;Swann et al 2009), and switching (Cheyne et al 2012;Gilbertson et al 2005;Stoffers et al 2001), to movement imagery (Brinkman et al 2014;Schnitzler et al 1997) and observation (Babiloni et al 2002;Koelewijn et al 2008;Orgs et al 2008, Pavlidou et al 2014. Furthermore, strong evidence for the motor function of the sensorimotor ␤-rhythm comes from the clear ␤-peak in the corticomuscular coherence: the coherence between the extracranial activity over the sensorimotor cortex and the EMG (Baker et al 1997;Salenius et al 1997).…”

Section: The Sensorimotor ␤-Rhythmmentioning

confidence: 69%

Distinct α- and β-band rhythms over rat somatosensory cortex with similar properties as in humans

Fransen

Dimitriadis

Ede

et al. 2016

Journal of Neurophysiology

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Fransen AM, Dimitriadis G, van Ede F, Maris E. Distinct ␣-and ␤-band rhythms over rat somatosensory cortex with similar properties as in humans. J Neurophysiol 115: 3030 -3044, 2016. First published March 23, 2016 doi:10.1152/jn.00507.2015.-We demonstrate distinct ␣-(7-14 Hz) and ␤-band (15-30 Hz) rhythms in rat somatosensory cortex in vivo using epidural electrocorticography recordings. Moreover, we show in rats that a genuine ␤-rhythm coexists alongside ␤-activity that reflects the second harmonic of the arch-shaped somatosensory ␣-rhythm. This demonstration of a genuine somatosensory ␤-rhythm depends on a novel quantification of neuronal oscillations that is based on their rhythmic nature: lagged coherence. Using lagged coherence, we provide two lines of evidence that this somatosensory ␤-rhythm is distinct from the second harmonic of the archshaped ␣-rhythm. The first is based on the rhythms' spatial properties: the ␣-and ␤-rhythms are demonstrated to have significantly different topographies. The second is based on the rhythms' temporal properties: the lagged phase-phase coupling between the ␣-and ␤-rhythms is demonstrated to be significantly less than would be expected if both reflected a single underlying nonsinusoidal rhythm. Finally, we demonstrate that 1) the lagged coherence spectrum is consistent between signals from rat and human somatosensory cortex; and 2) a tactile stimulus has the same effect on the somatosensory ␣-and ␤-rhythms in both rats and humans, namely suppressing them. Thus we not only provide evidence for the existence of genuine ␣-and ␤-rhythms in rat somatosensory cortex, but also for their homology to the primate sensorimotor ␣-and ␤-rhythms.

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“…According to this popular theory, the BG 12 circuit is able to process those requests and finally select the most salient (or urgent) 13 potential action, via the direct BG pathway, while providing inhibition to the rest 14 competing channels via the indirect pathway [6,7]. 15 An increasing amount of neurophysiological evidence implicates the BG to selection 16 of voluntary motor actions and provides indirect verification of this hypothesis [8]. [9] 17 showed that the excess activation of the direct BG pathway in freely behaving mice, via 18 stimulation of MSN D1 neurons in the striatum, increases movement, while the 19 stimulation of the indirect pathway made the same animals to freeze.…”

mentioning

confidence: 99%

“…In addition, 20 although both pathways are required for healthy action selection and were found to 21 contribute equally to the initiation of actions in [10], the indirect pathway is suppressed 22 during the execution of actions or action sequences [11], presumably because any 23 behavioural conflicts have already been resolved during movement [8]. 24 From another standpoint, low-frequency brain oscillations have been widely 25 implicated in both the function of the BG [12] and the process of decision 26 making [13][14][15][16][17]. Oscillations in the cortex mediate the processing of new 27 information [18], the dynamic formation of neural ensembles representing different 28 actions and the suppression of other task-irrelevant regions [19,20].…”

mentioning

confidence: 99%

“…In the literature, there is cumulative evidence that strong alpha power is able to inhibit 754 task-irrelevant regions in the cortex and thus control information flow [15,20,67]. This 755 theory, which is known as gating by inhibition [68], proposes that strong alpha activity 756 is caused by GABAergic interneurons, which silence neuronal firing by providing a GABAergic inhibition, or other brain regions, and whether this mechanism can operate 762 in the same spatial scale that is required to inhibit complete neural ensembles.…”

mentioning

confidence: 99%

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Assessing Selectivity in the Basal Ganglia: The “Gearbox” Hypothesis

Fountas

Shanahan

2017

Preprint

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Despite experimental evidence, the literature so far contains no systematic attempt to address the impact of cortical oscillations on the ability of the basal ganglia (BG) to select. In this study, we employed a state-of-the-art spiking neural model of the BG circuitry and investigated the effectiveness of this circuitry as an action selection device. We found that cortical frequency, phase, dopamine and the examined time scale, all have a very important impact on this process. Our simulations resulted in a canonical profile of selectivity, termed selectivity portraits, which suggests that the cortex is the structure that determines whether selection will be performed in the BG and what strategy will be utilized. Some frequency ranges promote the exploitation of highly salient actions, others promote the exploration of alternative options, while the remaining frequencies halt the selection process. Based on this behaviour, we propose that the BG circuitry can be viewed as the "gearbox" of action selection. Coalitions of rhythmic cortical areas are able to switch between a repertoire of available BG modes which, in turn, change the course of information flow within the cortico-BG-thalamo-cortical loop. Dopamine, akin to "control pedals", either stops or initiates a decision, while cortical frequencies, as a "gear lever", determine whether a decision can be triggered and what type of decision this will be. Finally, we identified a selection cycle with a period of around 200ms, which was used to assess the biological plausibility of the popular cognitive architectures. Author summaryOur brains are continuously called to select the most appropriate action between alternative competing choices. A plethora of evidence and theoretical work indicates that a fundamental brain region called the basal ganglia might be the locus where this competition occurs. But how is the winning choice determined each time? Using a detailed computational model, based on neurophysiological properties of this region, we suggest that, whereas the basal ganglia might indeed contain the circuitry of action selection, the cerebral cortex is, in fact, the brain region that dictates this process. Similarly to a gearbox in a car, the basal ganglia provide modes for the exploitation of the safest option (forward gears), exploration of alternative options (reverse gear) and a neutral state, in case that the selection process needs to be halted. Our results further indicate that the instructions for mode-switching are relayed to the basal ganglia through specific low frequencies of oscillations within cortical areas. Finally, we provide estimations for the frequency ranges that can be used to activate each selectivity mode, as well as the duration of the selection process under various conditions.

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Distinct Roles for Alpha- and Beta-Band Oscillations during Mental Simulation of Goal-Directed Actions

Cited by 168 publications

References 67 publications

Transcranial alternating current stimulation to the inferior parietal lobe decreases mu suppression to egocentric, but not allocentric hand movements

Transcranial alternating current stimulation to the inferior parietal lobe decreases mu suppression to egocentric, but not allocentric hand movements

Distinct α- and β-band rhythms over rat somatosensory cortex with similar properties as in humans

Assessing Selectivity in the Basal Ganglia: The “Gearbox” Hypothesis

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